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# SPDX-License-Identifier: GPL-2.0+
# Copyright (c) 2016 Google, Inc
# Written by Simon Glass <sjg@chromium.org>
#
# Class for an image, the output of binman
#
from collections import OrderedDict
import fnmatch
from operator import attrgetter
import os
import re
import sys
from binman.entry import Entry
from binman.etype import fdtmap
from binman.etype import image_header
from binman.etype import section
from dtoc import fdt
from dtoc import fdt_util
from patman import tools
from patman import tout
class Image(section.Entry_section):
"""A Image, representing an output from binman
An image is comprised of a collection of entries each containing binary
data. The image size must be large enough to hold all of this data.
This class implements the various operations needed for images.
Attributes:
filename: Output filename for image
image_node: Name of node containing the description for this image
fdtmap_dtb: Fdt object for the fdtmap when loading from a file
fdtmap_data: Contents of the fdtmap when loading from a file
allow_repack: True to add properties to allow the image to be safely
repacked later
Args:
copy_to_orig: Copy offset/size to orig_offset/orig_size after reading
from the device tree
test: True if this is being called from a test of Images. This this case
there is no device tree defining the structure of the section, so
we create a section manually.
"""
def __init__(self, name, node, copy_to_orig=True, test=False):
section.Entry_section.__init__(self, None, 'section', node, test=test)
self.copy_to_orig = copy_to_orig
self.name = 'main-section'
self.image_name = name
self._filename = '%s.bin' % self.image_name
self.fdtmap_dtb = None
self.fdtmap_data = None
self.allow_repack = False
if not test:
self.ReadNode()
def ReadNode(self):
section.Entry_section.ReadNode(self)
filename = fdt_util.GetString(self._node, 'filename')
if filename:
self._filename = filename
self.allow_repack = fdt_util.GetBool(self._node, 'allow-repack')
@classmethod
def FromFile(cls, fname):
"""Convert an image file into an Image for use in binman
Args:
fname: Filename of image file to read
Returns:
Image object on success
Raises:
ValueError if something goes wrong
"""
data = tools.ReadFile(fname)
size = len(data)
# First look for an image header
pos = image_header.LocateHeaderOffset(data)
if pos is None:
# Look for the FDT map
pos = fdtmap.LocateFdtmap(data)
if pos is None:
raise ValueError('Cannot find FDT map in image')
# We don't know the FDT size, so check its header first
probe_dtb = fdt.Fdt.FromData(
data[pos + fdtmap.FDTMAP_HDR_LEN:pos + 256])
dtb_size = probe_dtb.GetFdtObj().totalsize()
fdtmap_data = data[pos:pos + dtb_size + fdtmap.FDTMAP_HDR_LEN]
fdt_data = fdtmap_data[fdtmap.FDTMAP_HDR_LEN:]
out_fname = tools.GetOutputFilename('fdtmap.in.dtb')
tools.WriteFile(out_fname, fdt_data)
dtb = fdt.Fdt(out_fname)
dtb.Scan()
# Return an Image with the associated nodes
root = dtb.GetRoot()
image = Image('image', root, copy_to_orig=False)
image.image_node = fdt_util.GetString(root, 'image-node', 'image')
image.fdtmap_dtb = dtb
image.fdtmap_data = fdtmap_data
image._data = data
image._filename = fname
image.image_name, _ = os.path.splitext(fname)
return image
def Raise(self, msg):
"""Convenience function to raise an error referencing an image"""
raise ValueError("Image '%s': %s" % (self._node.path, msg))
def PackEntries(self):
"""Pack all entries into the image"""
section.Entry_section.Pack(self, 0)
def SetImagePos(self):
# This first section in the image so it starts at 0
section.Entry_section.SetImagePos(self, 0)
def ProcessEntryContents(self):
"""Call the ProcessContents() method for each entry
This is intended to adjust the contents as needed by the entry type.
Returns:
True if the new data size is OK, False if expansion is needed
"""
sizes_ok = True
for entry in self._entries.values():
if not entry.ProcessContents():
sizes_ok = False
tout.Debug("Entry '%s' size change" % self._node.path)
return sizes_ok
def WriteSymbols(self):
"""Write symbol values into binary files for access at run time"""
section.Entry_section.WriteSymbols(self, self)
def BuildImage(self):
"""Write the image to a file"""
fname = tools.GetOutputFilename(self._filename)
tout.Info("Writing image to '%s'" % fname)
with open(fname, 'wb') as fd:
data = self.GetData()
fd.write(data)
tout.Info("Wrote %#x bytes" % len(data))
def WriteMap(self):
"""Write a map of the image to a .map file
Returns:
Filename of map file written
"""
filename = '%s.map' % self.image_name
fname = tools.GetOutputFilename(filename)
with open(fname, 'w') as fd:
print('%8s %8s %8s %s' % ('ImagePos', 'Offset', 'Size', 'Name'),
file=fd)
section.Entry_section.WriteMap(self, fd, 0)
return fname
def BuildEntryList(self):
"""List the files in an image
Returns:
List of entry.EntryInfo objects describing all entries in the image
"""
entries = []
self.ListEntries(entries, 0)
return entries
def FindEntryPath(self, entry_path):
"""Find an entry at a given path in the image
Args:
entry_path: Path to entry (e.g. /ro-section/u-boot')
Returns:
Entry object corresponding to that past
Raises:
ValueError if no entry found
"""
parts = entry_path.split('/')
entries = self.GetEntries()
parent = '/'
for part in parts:
entry = entries.get(part)
if not entry:
raise ValueError("Entry '%s' not found in '%s'" %
(part, parent))
parent = entry.GetPath()
entries = entry.GetEntries()
return entry
def ReadData(self, decomp=True):
tout.Debug("Image '%s' ReadData(), size=%#x" %
(self.GetPath(), len(self._data)))
return self._data
def GetListEntries(self, entry_paths):
"""List the entries in an image
This decodes the supplied image and returns a list of entries from that
image, preceded by a header.
Args:
entry_paths: List of paths to match (each can have wildcards). Only
entries whose names match one of these paths will be printed
Returns:
String error message if something went wrong, otherwise
3-Tuple:
List of EntryInfo objects
List of lines, each
List of text columns, each a string
List of widths of each column
"""
def _EntryToStrings(entry):
"""Convert an entry to a list of strings, one for each column
Args:
entry: EntryInfo object containing information to output
Returns:
List of strings, one for each field in entry
"""
def _AppendHex(val):
"""Append a hex value, or an empty string if val is None
Args:
val: Integer value, or None if none
"""
args.append('' if val is None else '>%x' % val)
args = [' ' * entry.indent + entry.name]
_AppendHex(entry.image_pos)
_AppendHex(entry.size)
args.append(entry.etype)
_AppendHex(entry.offset)
_AppendHex(entry.uncomp_size)
return args
def _DoLine(lines, line):
"""Add a line to the output list
This adds a line (a list of columns) to the output list. It also updates
the widths[] array with the maximum width of each column
Args:
lines: List of lines to add to
line: List of strings, one for each column
"""
for i, item in enumerate(line):
widths[i] = max(widths[i], len(item))
lines.append(line)
def _NameInPaths(fname, entry_paths):
"""Check if a filename is in a list of wildcarded paths
Args:
fname: Filename to check
entry_paths: List of wildcarded paths (e.g. ['*dtb*', 'u-boot*',
'section/u-boot'])
Returns:
True if any wildcard matches the filename (using Unix filename
pattern matching, not regular expressions)
False if not
"""
for path in entry_paths:
if fnmatch.fnmatch(fname, path):
return True
return False
entries = self.BuildEntryList()
# This is our list of lines. Each item in the list is a list of strings, one
# for each column
lines = []
HEADER = ['Name', 'Image-pos', 'Size', 'Entry-type', 'Offset',
'Uncomp-size']
num_columns = len(HEADER)
# This records the width of each column, calculated as the maximum width of
# all the strings in that column
widths = [0] * num_columns
_DoLine(lines, HEADER)
# We won't print anything unless it has at least this indent. So at the
# start we will print nothing, unless a path matches (or there are no
# entry paths)
MAX_INDENT = 100
min_indent = MAX_INDENT
path_stack = []
path = ''
indent = 0
selected_entries = []
for entry in entries:
if entry.indent > indent:
path_stack.append(path)
elif entry.indent < indent:
path_stack.pop()
if path_stack:
path = path_stack[-1] + '/' + entry.name
indent = entry.indent
# If there are entry paths to match and we are not looking at a
# sub-entry of a previously matched entry, we need to check the path
if entry_paths and indent <= min_indent:
if _NameInPaths(path[1:], entry_paths):
# Print this entry and all sub-entries (=higher indent)
min_indent = indent
else:
# Don't print this entry, nor any following entries until we get
# a path match
min_indent = MAX_INDENT
continue
_DoLine(lines, _EntryToStrings(entry))
selected_entries.append(entry)
return selected_entries, lines, widths